Interdependencies between temperature and moisture sensitivities of CO&amp;lt;sub&amp;gt;2&amp;lt;/sub&amp;gt; emissions in European land ecosystems

Gritsch, Christine; Zimmermann, Michael; Zechmeister‐Boltenstern, Sophie

doi:10.5194/bg-12-5981-2015

Cited by 34 publications

(23 citation statements)

References 59 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Soil temperature explained most of the variability (47%) of soil respiration across land use types, with an additional 13% explained by soil moisture and bulk density, which confirms the findings of several previous studies on the controls of soil CO 2 respiration in terrestrial ecosystems (Carter et al, 2012;Gritsch et al, 2015;Imer et al, 2013;Luo et al, 2012;Schaufler et al, 2010;Skiba et al, 2013). The temperature dependence of soil respiration can be explained by the stimulation of biological activity (plant roots and microbial communities) with increasing temperature, and this was evident within all the investigated land use types as indicated by the MLR analysis (Table 2).…”

Section: Carbon Dioxide Fluxessupporting

confidence: 87%

“…Global methane emission controls include soil moisture or water table depth, soil carbon content, soil temperature and pH, and vegetation composition (Carter et al, 2012;Levy et al, 2012;Turetsky et al, 2014), but the relative importance of these controls varies depending on the spatial and temporal scales investigated (Dise, 1993;Levy et al, 2012) and also the ecosystem type. Soil temperature and moisture are also postulated as universal controls of respiratory CO 2 production across ecosystems (Gritsch, Zimmermann, & Zechmeister-Boltenstern, 2015).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Soil Greenhouse Gas Fluxes, Environmental Controls, and the Partitioning of N₂O Sources in UK Natural and Seminatural Land Use Types

Sgouridis

Ullah

2017

JGR Biogeosciences

View full text Add to dashboard Cite

Natural and seminatural terrestrial ecosystems (unmanaged peatlands and forests and extensive and intensive grasslands) have been under‐represented in the UK greenhouse gas (GHG) inventory. Mechanistic studies of GHG fluxes and their controls can improve the prediction of the currently uncertain GHG annual emission estimates. The source apportionment of N2O emissions can further inform management plans for GHG mitigation. We have measured in situ GHG fluxes monthly in two replicated UK catchments and evaluated their environmental controlling factors. An adapted 15N‐gas flux method with low addition of 15N tracer (0.03–0.5 kg 15N ha−1) was used to quantify the relative contribution of denitrification to net N2O production. Total N2O fluxes were 40 times higher in the intensive grasslands than in the peatlands (range: −1.32 to 312.3 μg N m−2 h−1). The contribution of denitrification to net N2O emission varied across the land use types and ranged from 9 to 60%. Soil moisture was the key parameter regulating the partitioning of N2O sources (r2 = 0.46). Total N2O fluxes were explained by a simple model (r2 = 0.83) including parameters such as total dissolved nitrogen, organic carbon, and water content. A parsimonious model with the soil moisture content as a single scalar parameter explained 84% of methane flux variability across land uses. The assumption that 1% of the atmospherically deposited N on natural ecosystems is emitted as N2O could be overestimated or underestimated (0.3–1.6%). The use of land use‐specific N2O emission factors and further information on N2O source partitioning should help constrain this uncertainty.

show abstract

Section: Carbon Dioxide Fluxessupporting

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Soil Greenhouse Gas Fluxes, Environmental Controls, and the Partitioning of N₂O Sources in UK Natural and Seminatural Land Use Types

Sgouridis

Ullah

2017

JGR Biogeosciences

View full text Add to dashboard Cite

show abstract

“…These fixed Q 10 values are widely used in ecosystem models (Foereid et al, ; Mahecha et al, ; Potter et al, ). Conversely, several studies have suggested that Q 10 is variable, with values ranging from 1 to more than 12 (Gritsch et al, ; Hamdi et al, ) and reaching 4.5 in Arctic tundra ecosystems (Ueyama et al, ). Globally, Q 10 seems to be amplified in Arctic ecosystems in comparison to temperate and tropical regions, perhaps due to an inverse correlation with mean annual temperature across biomes (Bekku et al, ; Zhou et al, ).…”

Section: Introductionmentioning

confidence: 99%

Temperature Response of Respiration Across the Heterogeneous Landscape of the Alaskan Arctic Tundra

et al. 2018

View full text Add to dashboard Cite

Predictions of the response of ecosystem respiration to warming in the Arctic are not well constrained, partly due to the considerable spatial heterogeneity of these permafrost-dominated areas. Accurate calculations of in situ temperature sensitivities of respiration (Q 10 ) are vital for the prediction of future Arctic emissions. To understand the impact of spatial heterogeneity on respiration rates and Q 10 , we compared respiration measured from automated chambers across the main local polygonized landscape forms (high and low centers, polygon rims, polygon troughs) to estimates from the flux-partitioned net ecosystem exchange collected in an adjacent eddy covariance tower. Microtopographic type appears to be the most important variable explaining the variability in respiration rates, and low-center polygons and polygon troughs show the greatest cumulative respiration rates, possibly linked to their deeper thaw depth and higher plant biomass. Regardless of the differences in absolute respiration rates, Q 10 is surprisingly similar across all microtopographic features, possibly indicating a similar temperature limitation to decomposition across the landscape. Q 10 was higher during the colder early summer and lower during the warmer peak growing season, consistent with an elevated temperature sensitivity under colder conditions. The respiration measured by the chambers and the estimates from the daytime flux-partitioned eddy covariance data were within uncertainties during early and peak seasons but overestimated respiration later in the growing season. Overall, this study suggests that it is possible to simplify estimates of the temperature sensitivity of respiration across heterogeneous landscapes but that seasonal changes in Q 10 should be incorporated into model simulations.

show abstract

“…After pre-incubation at 4°C for 6 days, soil samples were sequentially set to 5°C, 10°C, 15°C, 20°C, and 25°C by controlling the temperature of the water bath of the Respicond system. Samples were kept at each temperature for 24 h (see also Gritsch et al 2015). The first 12 h after each temperature rise were treated as equilibration time.…”

Section: Methodsmentioning

confidence: 99%

“…The authors criticized that sample preprocessing like sieving and storage might alter microbial biomass, microbial activity, microbial community composition, and the availability of substrate. However, storage is mostly inevitable for practical reasons (e.g., Gritsch et al 2015;Lefèvre et al 2014;Meyer et al 2017) and sieving (mostly to < 2 mm) is a common practice to remove roots, plant residues, and rock fragments and to ensure homogenization of the soil (e.g., Conant et al 2008;Fierer et al 2006;Wang et al 2016). Only few studies on Q10 were conducted using undisturbed and/or fresh samples (e.g., Miller and Geisseler 2018;Reichstein et al 2005) An alteration of SR and Q10 by sieving and storage might be straightforward if all soils were similarly affected.…”

Section: Introductionmentioning

confidence: 99%

Effect of sieving and sample storage on soil respiration and its temperature sensitivity (Q10) in mineral soils from Germany

2019

View full text Add to dashboard Cite

Knowledge about spatial patterns of soil respiration (SR) and its temperature sensitivity (Q10) is of emerging relevance for assessing carbon fluxes across the landscape. Related experiments are often conducted under controlled laboratory conditions and usually rely on soil samples, which are sieved and stored. Here, we investigated the effect of sieving and storage on SR and Q10. We took 14 samples from different land use types and soil textures. Samples were sieved to 2 mm at field-moist conditions and split into four treatments: sieved/no-storage, sieved/freeze-storage (−18°C), sieved/cold-storage (+ 4°C), and sieved/drystorage (+ 40°C). The storage time was 7 weeks. Intact soil cores were used as a control. The SR was not significantly affected by sieving/no-storage, sieving/freeze-storage, and sieving/cold-storage compared with the control. Yet, sieving/dry-storage significantly increased SR but all samples were similarly affected (r = 0.81 for the correlation between SR after sieving/dry-storage and SR in the control). The Q10 of sieving/no-storage (1.94 ± 0.28), sieving/freeze-storage (1.94 ± 0.23), sieving/cold-storage (2.37 ± 0.29), and sieving/dry-storage (2.29 ± 1.35) did not differ significantly from the control (2.12 ± 0.23). All samples responded similar to sieving and storage (r = 0.68-0.73 for the correlation between Q10 in each respective treatment and Q10 in the control), with the exception of sieved/dry-storage (r = 0.09). We conclude that sieving at field-moist conditions and subsequent freeze-or cold-storage is acceptable to derive SR and Q10 for the here reported storage time. Although dry-storage may be acceptable for the comparison of SR between samples, it should be avoided for realistic estimates of SR and for the determination of Q10.

show abstract

Interdependencies between temperature and moisture sensitivities of CO<sub>2</sub> emissions in European land ecosystems

Cited by 34 publications

References 59 publications

Soil Greenhouse Gas Fluxes, Environmental Controls, and the Partitioning of N₂O Sources in UK Natural and Seminatural Land Use Types

Soil Greenhouse Gas Fluxes, Environmental Controls, and the Partitioning of N₂O Sources in UK Natural and Seminatural Land Use Types

Temperature Response of Respiration Across the Heterogeneous Landscape of the Alaskan Arctic Tundra

Effect of sieving and sample storage on soil respiration and its temperature sensitivity (Q10) in mineral soils from Germany

Contact Info

Product

Resources

About

Interdependencies between temperature and moisture sensitivities of CO&lt;sub&gt;2&lt;/sub&gt; emissions in European land ecosystems

Cited by 34 publications

References 59 publications

Soil Greenhouse Gas Fluxes, Environmental Controls, and the Partitioning of N2O Sources in UK Natural and Seminatural Land Use Types

Soil Greenhouse Gas Fluxes, Environmental Controls, and the Partitioning of N2O Sources in UK Natural and Seminatural Land Use Types

Temperature Response of Respiration Across the Heterogeneous Landscape of the Alaskan Arctic Tundra

Effect of sieving and sample storage on soil respiration and its temperature sensitivity (Q10) in mineral soils from Germany

Contact Info

Product

Resources

About

Interdependencies between temperature and moisture sensitivities of CO<sub>2</sub> emissions in European land ecosystems

Soil Greenhouse Gas Fluxes, Environmental Controls, and the Partitioning of N₂O Sources in UK Natural and Seminatural Land Use Types

Soil Greenhouse Gas Fluxes, Environmental Controls, and the Partitioning of N₂O Sources in UK Natural and Seminatural Land Use Types